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Micro thermal shear stress sensor based on vacuum anodic bonding and bulk-micromachining

Micro thermal shear stress sensor based on vacuum anodic bonding and bulk-micromachining
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摘要 This paper describes a micro thermal shear stress sensor with a cavity underneath, based on vacuum anodic bonding and bulk micromachined technology. A Ti/Pt alloy strip, 2μm×100μm, is deposited on the top of a thin silicon nitride diaphragm and functioned as the thermal sensor element. By using vacuum anodic bonding and bulk-si anisotropic wet etching process instead of the sacrificial-layer technique, a cavity, functioned as the adiabatic vacuum chamber, 200μm×200μm×400μm, is placed between the silicon nitride diaphragm and glass (Corning 7740). This method totally avoid adhesion problem which is a major issue of the sacrificial-layer technique. This paper describes a micro thermal shear stress sensor with a cavity underneath, based on vacuum anodic bonding and bulk micromachined technology. A Ti/Pt alloy strip, 2μm×100μm, is deposited on the top of a thin silicon nitride diaphragm and functioned as the thermal sensor element. By using vacuum anodic bonding and bulk-si anisotropic wet etching process instead of the sacrificial-layer technique, a cavity, functioned as the adiabatic vacuum chamber, 200μm×200μm×400μm, is placed between the silicon nitride diaphragm and glass (Corning 7740). This method totally avoid adhesion problem which is a major issue of the sacrificial-layer technique.
出处 《Chinese Physics B》 SCIE EI CAS CSCD 2008年第6期2130-2136,共7页 中国物理B(英文版)
基金 Project supported by the National Natural Science Foundation of China (Grant No 60576053) Technology Innovation of Chinese Academy of Sciences (Grant No CXJJ-176)
关键词 thermal micro shear stress sensor vacuum anodic bonding bulk-micromachined thermal micro shear stress sensor, vacuum anodic bonding, bulk-micromachined
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参考文献14

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